US20100221090A1 - Cutter dome for reclaim system - Google Patents
Cutter dome for reclaim system Download PDFInfo
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- US20100221090A1 US20100221090A1 US12/394,990 US39499009A US2010221090A1 US 20100221090 A1 US20100221090 A1 US 20100221090A1 US 39499009 A US39499009 A US 39499009A US 2010221090 A1 US2010221090 A1 US 2010221090A1
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- Prior art keywords
- dome
- cutter
- chamber
- sidewall
- roof
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
- B65G—TRANSPORT OR STORAGE DEVICES, e.g. CONVEYORS FOR LOADING OR TIPPING, SHOP CONVEYOR SYSTEMS OR PNEUMATIC TUBE CONVEYORS
- B65G65/00—Loading or unloading
- B65G65/30—Methods or devices for filling or emptying bunkers, hoppers, tanks, or like containers, of interest apart from their use in particular chemical or physical processes or their application in particular machines, e.g. not covered by a single other subclass
- B65G65/34—Emptying devices
- B65G65/40—Devices for emptying otherwise than from the top
- B65G65/46—Devices for emptying otherwise than from the top using screw conveyors
- B65G65/466—Devices for emptying otherwise than from the top using screw conveyors arranged to be movable
Definitions
- the present invention relates to cutter domes for use with a reclaim system within a storage vessel.
- Silos are used for storing bulk material such as grains or powders.
- the bulk material is typically deposited into the silo through an opening formed at the top of the silo and is removed from the silo through an outlet centrally formed on the floor the silo.
- Bottom reclaim systems are often mounted on the floor of the silo for controlling movement of the bulk material to the outlet.
- the bottom reclaim system includes a base mounted adjacent to the outlet and an auger that outwardly projects from the base.
- the auger rotates about a central longitudinal axis thereof so as to inwardly draw the bulk material from the perimeter of the floor to the outlet.
- the auger also revolves around the central outlet on the silo floor. As a result, the auger draws bulk material to the outlet from all areas on the silo floor.
- FIFO first-in-first-out
- the dome introduces other problems.
- the bulk material can post on the roof of the dome.
- a significant portion of the entire amount of bulk material within the silo bears its load on a localized region.
- the bulk material can vertically stack on the roof of the dome in a cohesive structure that remains stationary as opposed to flowing out toward the auger.
- this stacked bulk material above the roof can bridge outward until it eventually reaches the interior surface of the silo.
- large cavities can be produced within the silo as the reclaimer removes the freely movable bulk material from below the bridging bulk material.
- the dome and reclaimer can be subject to tremendous point-loading caused by the bulk material. That is, whereas the entire weight of the bulk material is typically uniformly carried over the entire floor of the silo, posting of the bulk material causes the weight of a large percentage of the bulk material to be concentrated on the dome. This point loading of the bulk material can result in failure of the dome and/or reclaimer. Furthermore, the stacking and bridging of the bulk material and the resulting formation of cavities precludes efficient operation of the reclaimer and prevents FIFO flow of bulk material within the silo. In some situations, movement of the bulk material within the silo can be completely stopped. In turn, disrupting the stacked bulk material within the silo to restore proper flow of the bulk material can be time consuming and dangerous.
- FIG. 1 is a cut away perspective view of a storage vessel housing an inventive reclaim system
- FIG. 2 is an enlarged perspective view of the reclaim system mounted on the floor of the storage vessel shown in FIG. 1 ;
- FIG. 3 is an enlarged perspective view of the reclaim system shown in FIG. 2 having a cutter dome;
- FIG. 4 is a cross sectional side perspective view of the reclaim system with cutter dome shown in FIG. 3 ;
- FIG. 5 is a perspective view of an upper portion of the cutter dome shown in FIG. 3 ;
- FIG. 6 is a bottom perspective view of the cutter dome portion shown in FIG. 5 ;
- FIG. 7 is a side perspective view of the cutter dome portion shown in FIG. 5 wherein a portion of the sidewall has been removed;
- FIG. 7A is a side view of the flutes of the cutter dome portion shown in FIG. 7 ;
- FIG. 8 is a top perspective view of the reclaim system shown in FIG. 3 with a door of the cutter dome in an open position;
- FIG. 9 is a top perspective view of the reclaim system shown in FIG. 8 wherein the door is in a closed position;
- FIG. 10 is a cross sectional side view of the cutter dome with a door for the upper dome portion in a partially open position
- FIG. 11 is a side perspective view of an alternative embodiment of a cutter dome portion formed of flat flutes wherein a portion of the sidewall is removed;
- FIG. 12 is a side perspective view of another alternative embodiment of a cutter dome portion having radially outwardly projecting inlets
- FIG. 13A is a side perspective view of an alternative embodiment of a cutter dome portion having a frusticonical roof portion that slopes radially inward;
- FIG. 13B is a side perspective view of alternative embodiment of a cutter dome portion having a frusticonical roof portion that slopes radially outward;
- FIG. 14 is a cross section side view of an alternative embodiment of a reclaim system having a cutter dome with an exposed central shaft and encircling flutes;
- FIG. 15 is a top plan view of the reclaim system shown in FIG. 14 ;
- FIG. 16 is a top plan view of the roof of the reclaim system shown in FIG. 14 without the shaft;
- FIG. 17 is an alternative embodiment of a reclaim system having a further alternative embodiment of a dome cutter
- FIG. 18 is a top plan view of the reclaim system shown in FIG. 17 ;
- FIG. 19 is a top plan view of the roof of the cutter dome shown in FIG. 17 ;
- FIG. 20 is a cross sectional side perspective view of an alternative embodiment of a reclaim system having a cutter dome wherein an upper portion of the cutter dome is rotatable independent of a lower portion of the cutter dome;
- FIG. 21 is a top perspective view of an alternative embodiment of an upper dome portion with a door in an open position
- FIG. 22 is a top perspective view of the upper dome portion shown in FIG. 21 with the door in a closed position;
- FIG. 23 is a bottom perspective view of the upper dome portion shown in FIG. 21 with the door in the open position;
- FIG. 24 is a bottom perspective view of the upper dome portion shown in FIG. 23 with the door in the closed position;
- FIG. 25 is a bottom plan view of the upper dome portion shown in FIG. 21 with the door in the open position;
- FIG. 26 is a bottom plan view of the upper dome portion shown in FIG. 25 with the door in the closed position.
- FIG. 1 Depicted in FIG. 1 is one embodiment of a reclaim system 10 incorporating features of the present invention and being used in association with a storage vessel 12 .
- Storage vessel 12 is shown as comprising a substantially cylindrical sidewall 14 that extends between a floor 16 and a cap 18 .
- Storage vessel 12 has an interior surface 20 that bounds a compartment 22 that extends between floor 16 and cap 18 .
- An access area 24 is formed below floor 16 .
- Compartment 22 is configured to receive bulk material.
- the term “bulk material” is broadly intended to include powders, grains, sand, chips, granulated material, and other small diameter material that is capable of flowing under the force of gravity.
- Bulk materials typically have an average particle diameter size less than about 4 cm, commonly less than about 2 cm, and often less than 1 cm.
- Common examples of bulk materials include cement, talc, fly ash, salt, chemicals, fertilizers, wood chips, minerals, bauxite, coal, sulfur, beans, grains, such as wheat, barley, corn, oats, and rice, and flour and meal made from beans and grains.
- a variety of other small diameter materials can also function as bulk materials.
- Storage vessel 12 need not have a cylindrical configuration but can have a variety of different sizes, shapes and configurations.
- storage vessel 12 can comprise a silo, tank, dome, or any other type of building structure that bounds a compartment in which bulk material can be stored.
- Bulk material is typically fed into compartment 22 through an upper end of storage vessel 12 such as through cap 18 or an upper end of sidewall 14 . This feeding can be accomplished through any conventional means such as conveyor belts, pumps, augers, or the like.
- the bulk material is removed from compartment 22 through an opening in floor 16 .
- Reclaim system 10 regulates the flow of the bulk material through the opening in floor 16 .
- reclaim system 10 generally comprises a base 26 , a hopper 40 , a cutter dome 70 , and a reclaimer 180 .
- Base 26 is mounted on floor 16 .
- base 26 has a top side 28 and an opposing bottom side 30 .
- base 26 has an interior surface 32 that bounds a passage 34 extending therethrough between sides 28 and 30 .
- Passage 34 is the opening through which the bulk material passes out of compartment 22 of storage vessel 12 .
- base 26 comprises an outer structure 31 that encircles passageway 34 and is rigidly secured to floor 16 of storage vessel 12 ( FIG. 1 ).
- Base 26 also includes an inner structure 33 that at least partially encircles passageway 34 and is disposed radially inward and/or on top of outer structure 31 .
- Inner structure 33 is movably mounted on outer structure 31 so that inner structure 33 can rotate about passageway 34 relative to outer structure 31 .
- a variety of different structures can be formed between inner structure 33 and outer structure 31 to facilitate smooth and easy movement of inner structure 33 .
- a smooth wear plate, race, or other bearing assembly can be formed between inner structure 33 and outer structure 31 .
- cutter dome 70 is mounted on inner structure 33 of base 26 so that cutter dome 70 can also rotate relative to outer structure 31 of base 26 .
- outer structure 31 of base 26 is comprised of structural members, such as structural steel, and is mounted on or embedded within floor 16 .
- Floor 16 is typically comprised of reinforced concrete.
- outer structure 31 of base 26 can simply comprise the portion of floor 16 that surrounds passageway 34 extending through floor 16 .
- Inner structure 33 can then be movably secured to floor 16 .
- hopper 40 Mounted on outer structure 31 of base 26 so as to project below floor 16 and into access area 24 ( FIG. 1 ) is hopper 40 .
- Hopper 40 has an encircling sidewall 36 with an exterior surface 27 and an interior surface 42 that each extend between an upper end 44 and an opposing lower end 46 .
- Interior surface 42 bounds a chamber 48 within hopper 40 .
- An opening 50 is formed at upper end 44 of hopper 40 so that open communication is provided between passage 34 of base 26 and chamber 48 of hopper 40 .
- an opening 52 is formed at lower end 46 of hopper 40 in communication with chamber 48 .
- doors 54 can be mounted at lower end 46 of hopper 40 for selectively opening and closing opening 52 .
- a conveyor belt, transfer pipe, vehicle loading dock, railroad track or other means for transferring the bulk material away from hopper 40 can be disposed below doors 54 .
- doors 54 when doors 54 are open, bulk material that is transferred into hopper 40 can be deposited on the means for transferring the bulk material so as to convey the bulk material away from storage vessel 12 .
- cutter dome 70 rotatably mounted on base 26 is cutter dome 70 .
- cutter dome 70 is referred to as a “dome,” this is simply a term of art and cutter dome 70 need not have a conventional “dome” shaped configuration with an arched roof Rather, cutter dome 70 can have a substantially cylindrical configuration or a variety of other enclosing configurations.
- cutter dome comprises a lower dome portion 72 and an upper dome portion 74 .
- a rotational axis 76 about which cutter dome 70 rotates, centrally extends down through cutter dome 70 .
- lower dome portion 72 includes a lower sidewall 78 that extends from a lower end 80 to an upper end 82 .
- lower sidewall 78 has a tubular, cylindrical configuration that at least partially encircles rotational axis 76 .
- Lower sidewall 78 can also have a polygonal, irregular or other configuration.
- Lower end 80 is mounted on inner structure 33 of base 26 so that cutter dome 70 rotates about rotational axis 76 concurrently with inner structure 33 of base 26 .
- Lower sidewall 78 has an interior surface 84 that bounds a first chamber 86 .
- An inlet opening 89 is formed at upper end 82 while an outlet opening 90 is formed at lower end 80 .
- Outlet opening 90 communicates with passage 34 of base 26 so that bulk material can pass therebetween.
- a collection opening 88 is formed through lower sidewall 78 so that fluid communication is provided between compartment 22 of storage vessel 12 ( FIG. 1 ) and first chamber 86 .
- Collection opening 88 can be formed through lower sidewall 78 so that a portion of lower sidewall 78 forms a continuous loop about rotational axis 76 .
- collection opening 88 can be formed by forming a gap in lower sidewall 78 so that lower sidewall 78 has a substantially C-shaped configuration.
- a reclaimer such as an auger extends through collection opening 88 for drawing bulk material into first chamber 86 .
- upper dome portion 74 comprises an upper sidewall 94 that is mounted on upper end 82 ( FIG. 4 ) of lower sidewall 78 and that extends between a lower end 96 and an upper end 98 .
- Upper sidewall 94 has a substantially cylindrical configuration that completely encircles rotational axis 76 .
- Upper sidewall 94 can also have a polygonal, irregular, or other configuration.
- upper sidewall 94 has an interior surface 100 that bounds a second chamber 102 .
- upper end 98 of upper sidewall 94 terminates at a perimeter edge 104 .
- Perimeter edge 104 is comprised of three equal arced segments 106 A-C each having a substantially identical configuration.
- Arced segment 106 A comprises a top edge 108 A that extends from a first end 110 A to an opposing second end 112 A.
- Top edge 108 A has a constant radius relative to rotational axis 76 and downwardly slopes from first end 110 A to second end 112 A. As a result, first end 110 A is positioned higher along rotational axis 76 than second end 112 A.
- Arced segment 106 A also comprises a shoulder 114 A that downwardly projects from first end 11 A.
- shoulder 114 A extends in a plane that is parallel to and aligned with rotational axis 76 .
- shoulder 114 A can extend in a plane that intersects with rotational axis 76 at an angle.
- Arced segment 106 A can be configured so that an angle ⁇ 1 is formed between top edge 108 A and shoulder 114 A in a range between about 45° to about 225° with about 65° to about 115° or about 80° to about 110° being more common. Other angles can also be used. It is also appreciated that shoulder 114 A need not be straight but can also be curved.
- Arced segments 106 B and 106 C have the same configuration as arced segment 106 A and are identified by like reference characters. It is noted that the second end 112 of each arced segment 106 intersects with shoulder 114 of the adjacent arced segment 106 .
- roof 122 Centrally disposed within second chamber 102 of upper dome portion 74 is a shaft 120 that extends along rotational axis 76 .
- Upper dome portion 74 also comprises a roof 122 that extends between perimeter edge 104 and shaft 120 .
- roof 122 is comprised of three equal roof segments 124 A-C each having substantially the same circular segment configuration.
- Roof segment 124 A comprises an inside edge 126 A that is secured to shaft 120 , a curved outside edge 128 A that extends along top edge 108 A of perimeter edge 104 , a cutting edge 130 A that extends from shaft 120 to first end 110 A of top edge 108 A, and a back edge 132 A that extends from shaft 120 to second end 112 A of top edge 108 A.
- roof segment 128 A is curved so that inside edge 126 A of roof segment 124 A curves along shaft 120 at substantially the same angle as outside edge 128 A. This curve is such that if roof segment 124 A was extended, segment 124 A would encircle shaft 120 in a downwardly extending helical configuration.
- Roof segments 124 B and 124 C are similarly mounted so as to extend between shaft 120 and top edges 108 B and 108 C, respectively.
- elongated inlets 138 A-C are formed between cutting edge 130 of each roof segment 124 and back edge 132 of the adjacent roof segment 124 .
- inlet 138 C extends between shoulder 114 C and shaft 120 between cutting edge 130 C and back edge 132 A.
- the height of inlet 138 C depends on the height of shoulders 114 A-C and the angle at which the roof segments 124 A-C are disposed.
- Inlets 138 A-C provide fluid communication between compartment 22 of storage vessel 12 ( FIG. 1 ) and second chamber 102 of upper dome portion 74 .
- each flute 140 A-C is disposed between shaft 120 and upper sidewall 94 and extends from the back edge 132 of a corresponding roof segment 124 to a termination point located above a drop box 142 that is formed within second chamber 102 .
- Each flute 140 A-C downwardly slopes in a helical path about shaft 120 .
- each flute 140 A-C partially bounds a corresponding passageway 143 A-C through which the bulk material travels as it passes from a corresponding inlet 138 A-C to drop box 142 .
- Each passageway 143 A-C also downwardly slopes in a helical path about shaft 120 .
- Each flute 140 A-C slopes down toward drop box 142 so that the bulk material travels downward as cutter dome 70 is rotated.
- flutes 140 A-C are typically disposed at an angle less than the angle of repose of the bulk material within compartment 22 of storage vessel 12 . This helps prevent the bulk material from freely flowing down passageways 143 A-C.
- each flute 140 A-C typically slopes at an angle ⁇ 2 , which is relative to a plane that is normal to rotational axis 76 , that is in a range between about 5° to about 30° and more commonly in a range between about 10° to about 20°. Other ranges can also be used.
- the bulk material typically has an angle of repose within compartment 22 that is greater than about 30° relative to the horizontal.
- drop box 142 comprises a first partition wall 144 that extends along the height of upper sidewall 94 , an opposing second partition wall 145 that downwardly projects from the terminal end of flute 140 C, an outside partition wall 146 that slopes inwardly and extends between the outside ends of partition walls 144 and 145 , and an inside partition wall 147 that extends between the inside ends of partition walls 144 and 145 .
- the partition walls 144 - 147 bound an outlet 152 that provides fluid communication between first chamber 86 of lower dome portion 72 ( FIG. 4 ) and second chamber 102 of upper dome portion 74 .
- a door 154 ( FIG. 10 ) is hingedly mounted on inside partition wall 147 and can be used for selectively opening and closing outlet 152 .
- cutter dome 70 is rotated on base 26 about rotational axis 76 .
- the bulk material sitting on roof 122 passes into inlets 138 A-C, travels down passageways 143 A-C, and passes through outlet 152 in drop box 142 into first chamber 86 of lower dome portion 72 .
- the bulk material then travels down through passage 34 in base 26 and into chamber 48 of hopper 40 .
- inlets 138 A-C are positioned below cutting edges 130 A-C enables cutting edges 130 A-C to efficiently cut away at the bulk material as cutter dome 70 is rotated, thereby ensuring that the bulk material is fed into passageways 143 A-C.
- cutter dome 70 can come in a variety of different configurations.
- upper dome portion 74 is separately formed and secured to lower dome portion 72 such as by bolting, welding, or the like.
- the lower sidewall 78 and upper sidewall 94 can be formed from one or more continuous members that extend the full height of lower sidewall 78 and upper sidewall 94 .
- the depicted embodiment includes three inlets 138 A-C and three separate flutes 140 A-C.
- cutter dome 70 can be formed from a single inlet 138 and a single flute 140 or, alternatively, from two or four or more inlets 138 and flutes 140 .
- shoulders 114 A-C can be eliminated so that roof 122 is substantially flat.
- Inlets 138 A-C can be formed on flat roof 122 leading to passageways 143 A-C.
- roof 122 can be conical, domed shaped, semi-spherical or any other configuration.
- shoulders 114 A-C can be formed so as to expose cutting edges 130 A-C or shoulders 114 A-C can be eliminated so that inlets 138 A-C are formed flat on the roof surface.
- flutes 140 A-C are secured to roof segments 124 A-C such as by welding, bolting or other conventional methods.
- each roof segment 124 A-C can be integrally formed as a unitary member with a corresponding flute 140 A-C.
- each flute 140 A-C is shown as only partially encircling shaft 120 .
- each flute 140 A-C can form one or more complete helical revolutions about shaft 120 . Further alternative embodiments will be discussed below in greater detail.
- reclaimer 180 comprises an elongated auger 182 having a first end 184 that is disposed within the first chamber 86 and an opposing second end 186 that is disposed outside of cutter dome 70 but within storage vessel 12 .
- Auger 182 comprises a central shaft 188 having a central longitudinal axis 190 extending along the length thereof and one or more threads 192 helically encircling and extending along the length of shaft 188 .
- Auger 182 passes out of first chamber 86 by passing through collection opening 88 .
- a drive train 204 disposed within chamber 48 of hopper 40 and first chamber 86 of lower dome portion 72 is a drive train 204 .
- Drive train 204 has a first end 205 that is coupled by a belt to a drive motor 206 ( FIG. 3 ).
- Drive train 204 has an opposing second end 208 that is coupled with first end 184 of auger 182 .
- drive motor 206 and drive train 204 facilitate rotation of auger 182 about axis 190 ( FIG. 3 ) which in turn causes auger 182 to draw the bulk material into collection opening 88 .
- second end 208 of drive train 204 and first end 184 of auger 182 FIG.
- second end 208 of drive train 204 and first end 184 of auger 182 rotate concurrently with inner structure 33 of base 26 and cutter dome 70 about rotational axis 76 .
- Support arm 194 disposed parallel to and extending along the length of auger 182 is a support arm 194 .
- Support arm 194 has a first end 195 disposed within first chamber 86 and an opposing second end 197 disposed adjacent to second end 186 of auger 182 .
- Second end 186 of auger 182 is rotatable mounted to second end 197 of support arm 194 to provide structural stability to auger 188 .
- support arm 194 has an inside face 196 having a concave configuration and that extends along auger 182 . Inside face 196 helps to capture bulk material between threads 192 and inside face 196 so that the bulk material is efficiently drawn down along the length of auger 182 and into collection opening 88 .
- a drive shaft 198 is disposed within and extends along the length of support arm 194 .
- Drive shaft 198 is rotated by a motor 199 .
- drive shaft 198 has a distal end 201 located at second end 197 of support arm 194 .
- Distal end 201 couples with a track, such as through the use of a gear.
- the track is formed on the interior surface of 20 of storage vessel 12 adjacent to floor 16 so as to encircle floor 16 .
- the track can be formed on floor 16 at the perimeter edge thereof so as to encircle floor 16 .
- Drive shaft 198 is engaged with the track so that rotation of drive shaft 198 causes distal end 210 of drive shaft 198 to slowly move along the length of the track. In turn, this movement of drive shaft 198 causes second end 197 of support arm 194 and second end 186 of auger 182 to also move along the track. In turn, movement of the second end of support arm 194 and auger 182 along the track facilitates the rotation of second end 208 of drive train 204 , first end 184 of auger 182 , inner structure 33 of base 26 , and cutter dome 70 to concurrently rotate about rotational axis 76 .
- Reclaimer 180 hopper 40 , base 26 and the drive systems disclosed herein can be purchased from Laidig Systems, Inc. located in Mishawaka, Indiana. In alternative embodiments, it is appreciated that other conventional reclaimers, hoppers, bases and drive systems can be used with the inventive cutter domes of the present invention.
- reclaimer 180 can comprise different rotating screw configurations, belt conveyors with or without paddles, chain conveyors, and other types of continuous dragging or transport systems that are commonly used for movement of bulk material and which could function for moving bulk material into first chamber 86 .
- a door 214 encircles shaft 188 of auger 182 and can selectively move along shaft 188 .
- Door 214 is moveable between an open position and a closed position. In the open position shown in FIG. 8 , door 214 is drawn back from collection opening 88 into first chamber 86 so that bulk material can be drawn into cutter dome 70 through collection opening 88 during rotation of auger 182 . In the closed position shown in FIG. 9 , door 214 is moved forward so as to close off collection opening 88 .
- Door 214 is selectively moved between the open and close position as a result of a linkage 216 operated by a hydraulic piston 218 .
- Linkage 216 used to close door 214 cams over, thereby locking door 214 into position in case of hydraulic pressure loss.
- Other mechanisms can also be used for selectively opening and closing door 214 .
- the opening and closing of door 214 also facilitates selective opening and closing of door 154 that selectively covers outlet 152 of upper dome portion 74 .
- door 154 is hingedly mounted to inside partition wall 147 .
- the force of gravity enables door 154 to rotate downward into an open position so that bulk material can pass through outlet 152 .
- a top end 222 of door 214 pushes against door 154 causing it to rotate upward into a closed position and thereby close off outlet 152 .
- top end 222 of door 214 pushes against door 154 so as to prevent unwanted opening of door 154 .
- tapered rams 223 or other structures can be formed at top end 222 of door 214 to help facilitate closing of door 154 . Again, the closing of door 154 is desirable so that all the bulk material can be removed from within cutter dome 70 and hopper 40 for accessing the mechanisms therein.
- door 154 can be opened using a variety of different mechanisms such as screw drives, hydraulic pistons or a variety of other conventional systems. As such, doors 154 and 214 can be opened and closed separate from each other.
- the present design elements the need for a second drive mechanism to close door 154 , ensures concurrent closure of both doors, and provides an easy retrofit of adding an upper dome portion 74 on an existing lower dome portion 72 .
- Auger 182 begins to rotate about rotational axis 190 so as to draw the bulk material through collection opening 88 and into first chamber 86 of cutter dome 70 .
- cutter dome 70 and auger 182 begin to slowly rotate about rotational axis 76 as a result of the rotation of drive shaft 198 .
- Cutter dome 70 and auger 182 typically rotate at a rate of about 1-3 degrees per minute although other rates can also be used. The movement of auger 182 over floor 16 ensures a uniform draw down of the bulk material over floor 16 of storage vessel 12 .
- the bulk material positioned above cutter dome 70 is drawn into inlets 138 A-C where it passes down through second chamber 102 and into first chamber 86 through outlet 152 .
- the removal of the bulk material from above cutter dome 70 helps to maintain movement of the bulk material directly above cutter dome 70 .
- the bulk material is precluded from setting up or becoming stationary, thereby precluding “posting” or “bridging” of the bulk material above cutter dome 70 .
- the slow rotation of cutter dome 70 controls the material flow such that “rat holing” does not develop. Angling the flutes at a angle lower than the angle of repose of the bulk material also preclude unwanted free flow of material.
- the majority of the bulk material is collected through collection opening 88 . As a result, the bulk material is primarily processed through storage vessel 12 in a first-in-first-out inventory.
- first chamber 86 Once the bulk material passes into first chamber 86 from either collection opening 88 or through cutter dome 70 , the bulk material flows under the force of gravity through passageway 34 in base 26 and into chamber 48 of hopper 40 . The bulk material is then transferred out of hopper 40 through doors 54 using any conventional means such as trucks, conveyor belts, pumps, or the like.
- FIG. 11 Depicted in FIG. 11 is an alternative embodiment of an upper dome portion 74 A of cutter dome 70 .
- Like elements between upper dome portion 74 and 74 A are identified by like reference characters.
- roof segments 124 A-C and flutes 140 A-C are bent or contoured so as to extend in a smooth helical path.
- each roof segment 124 A-C is comprised of a flat plate in the form of a circular segment that extends from shaft 120 to perimeter edge 104 .
- each inlet 138 A-C has a substantially triangular configuration.
- the flutes 140 A-C are comprised of a series of flat circular segment plates 230 having a configuration similar to the flat roof segments 124 A-C.
- Each segment plate 230 has an inside edge 234 that is connected to shaft 120 , an opposing arced outside edge 236 that connects to sidewall 94 , and a first edge 238 and an opposing second edge 240 extending therebetween.
- Plates 230 are secured in sequential order with outside edges 236 being aligned longitudinally and adjacent inside edges 234 being vertically staggered along shaft 120 .
- a triangular riser 232 extends between second edge 240 of one plate 230 and first edge 238 of the adjacent plate 230 , thereby forming a stepped helical path about shaft 120 .
- upper dome portion 74 depicted in FIG. 5 , inlets 138 A-C extended only along roof 122 .
- upper dome portion 74 can also be formed so that the inlets for receiving the bulk material project out beyond upper sidewall 94 .
- FIG. 12 depicted in FIG. 12 is an alternative embodiment of an upper dome portion 74 B of cutter dome 70 where like elements are identified by like reference characters.
- upper sidewall 94 is formed from three sidewall sections 246 A-C. Each sidewall section 246 extends from a leading edge 248 to a tail edge 250 . Each sidewall section 246 A-C radially inwardly curves toward shaft 120 as it extends between ends 248 and 250 .
- leading end 248 has a radius from shaft 120 that is greater than the radius between shaft 120 and tail edge 250 .
- inlets 138 A-C now outwardly project beyond the adjacent sidewall section 246 .
- elongated inlets 252 A-C extends along the length of each sidewall section 246 . This inlet again captures bulk material and transfers it into first chamber 86 as cutter dome 70 is rotated.
- inlets 138 A-C extended all the way to upper sidewall 94 .
- the inlets 138 A-C need not extend all the way to sidewall 94 .
- FIG. 13A depicted in FIG. 13A is a further embodiment of an upper dome portion 74 C of cutter dome 70 where like elements are identified by like reference characters.
- Upper dome portion 74 C includes upper sidewall 94 .
- roof 122 comprises an outer roof portion 254 and an inner roof portion 256 .
- Outer roof portion 254 has a frusticonical configuration that slopes down and radially inward toward inner roof portion 256 .
- inner roof portion 256 comprises roof segments 124 A-C as previously discussed with regard to upper dome portion 74 .
- outer roof 254 functions to funnel bulk materials down to inner roof portion 256 which in turn transfers the bulk material to first chamber 86 .
- FIG. 13B Depicted in FIG. 13B is a further alternative embodiment of an upper dome portion 74 D.
- Upper dome portion 74 D is substantially the same as upper dome portion 74 C except that outer roof portion 254 has been replaced with an outer roof portion 258 .
- Outer roof portion 258 also has a frusticonical configuration but slopes down and away from inner roof portion 256 .
- outer roof portion 258 facilitates moving the bulk material off of cutter dome 70 .
- the inner and outer roof portions can rotate concurrently with each other and with lower dome portion 72 .
- inner roof portion 256 can rotate independent of the outer roof portion and/or lower dome portion 72 .
- a drive motor can be used to rotate inner roof portion 256 at a speed greater than lower dome portion 72 .
- FIGS. 14 and 15 Depicted in FIGS. 14 and 15 is an alternative embodiment of a cutter dome 70 A wherein like elements are identified by like reference characters.
- Cutter dome 70 A comprises lower dome portion 72 and an upper dome portion 74 E.
- Upper dome portion 74 E comprises a roof 260 mounted on lower dome portion 72 .
- Roof 260 comprises a circular frusticonical sidewall 262 that slopes radially inwardly and up to a central recess 264 .
- Recess 264 is bounded by a circular sidewall 265 and a floor 266 .
- floor 266 has a pair of openings 268 A and B which are selectively opened and closed by doors 270 A and B.
- openings 268 A and B connect by passageways to drop box 142 ( FIG. 7 ).
- shaft 120 extending through floor 270 is shaft 120 .
- One or more flutes 272 are helically formed on the exterior of shaft 120 . Flutes 272 projects out so as to be adjacent to sidewall 265 of recess 264 . As a result, flutes 272 block the free flow of bulk material into openings 268 A and B.
- lower dome portion 72 and upper dome portion 74 can rotate concurrently so that as shaft 120 is rotated, the bulk material passes down along flutes 272 and into openings 268 A and B.
- a separate drive motor within lower dome portion 72 can be used to selectively rotate shaft 120 independent of lower dome portion 72 and roof 260 .
- roof 260 can be configured similar to outer roof portion 254 ( FIG. 13A ) so that the bulk material is funneled toward recess 264 as opposed to away from recess 264 .
- FIGS. 17-19 is a further alternative embodiment of a cutter dome 70 B incorporating features of the present embodiment.
- Cutter dome 70 B comprises lower dome portions 72 having a roof 280 formed thereon. Roof 280 has a pair of openings 282 A and B that are selectively opened and closed by doors 284 A and B respectively.
- Shaft 120 centrally extends through roof 280 .
- a flute 286 is mounted on and helically encircles the exterior surface of shaft 120 .
- a drive mechanism disposed within lower dome portion 72 facilitates rotation of shaft 120 independent of lower dome portion 72 . With doors 284 A and B open, rotation of shaft 120 causes the bulk material to travel down the flute and into inlets 282 A and B. The bulk material then passes from inlets 282 A and B through lower dome portion 72 and into hopper 40 .
- Flute 286 is intended to project out to the edge of roof 280 so as to preclude any posting of the bulk material on roof 280 .
- upper dome portion 74 can rotate independent of lower dome portion 72 . That is, upper dome portion 74 can rotate at a different speed than lower dome portion 72 .
- FIG. 20 Depicted in FIG. 20 is one embodiment of how to facilitate such movement between dome portions 72 and 74 .
- upper dome portion 74 connects within lower dome portion 72 on a track 290 .
- Track 290 permits rotation of upper dome portion 74 relative to lower dome portion 72 and can comprise a smooth wear plate, race, bearing assembly or the like.
- An annular engagement track 292 is disposed on the interior surface of upper dome portion 74 having a plurality of teeth 294 formed thereon.
- a gear 296 engages teeth 294 .
- FIGS. 21-26 Depicted in FIGS. 21-26 is a further alternative embodiment of an upper dome portion 310 incorporating features of the present invention.
- Upper dome portion 310 is similar to upper dome portion 74 shown in FIGS. 5-7 and like elements are identified by like reference numbers. It is noted that part of the upper sidewall 94 of upper dome portion 310 is removed to help show the internal structure.
- upper dome portion 310 is shown having three roof segments 124 A-C and three inlets 138 A-C. However, in contrast to upper dome portion 74 wherein all three of passageways 143 terminate at a common outlet 152 , upper dome portion 310 , as shown in FIG. 21 , includes three flutes 312 A-C leading from corresponding inlets 138 A-C, respectively. Each flute 312 A-C extends a short distance in a downward, helical path about shaft 120 and terminates, as shown in FIG. 23 , at a separate outlet 316 A-C, respectively. That is, each flute 312 A-C which partially bounds a corresponding passageway 314 A-C terminates at a separate, isolated outlet 316 A-C.
- Each outlet 316 A-C is shown having a wedge shaped configuration and downwardly communicates with first chamber 86 of lower dome portion 72 ( FIG. 4 ). Because passageways 314 A-C are shorter than the passageways of upper dome portion 74 and each exits through its own outlet 316 A-C, there is less chance of bulk material clogging within upper dome portion 310 .
- a door 318 is mounted within second chamber 102 below outlets 316 A-C.
- Door 318 is shown in the form of a circular plate having three openings 319 A-C. Each opening 319 A-C has a wedge shaped configuration complementary to outlets 316 A-C.
- Door 318 centrally rotates about shaft 120 and is movably supported around it perimeter edge by supports 320 secured to upper sidewall 94 .
- a beam 336 is shown spanning between opposing sides of upper sidewall 94 and supports shaft 120 .
- Actuator 322 includes a body 324 having a first end 328 hingedly mounted to upper sidewall 94 and an opposing second end 330 .
- a piston 326 has a first end 332 slidably mounted within second end 330 of body 324 and an opposing second 334 hingedly mounted to a bottom surface of door 318 .
- actuator 322 can comprise a pneumatic or hydraulic piston.
- actuator 322 can comprise a screw drive or any other actuator that can expand and contract.
- Actuator 322 and door 318 are movable between an open and closed position.
- openings 319 A-C on door 318 ( FIG. 23 ) are aligned with outlets 316 A-C, respectively, so that the bulk material can freely flow out through outlets 316 A-C and into first chamber 86 .
- piston 326 advances out of body 324 , thereby causing door 318 to rotate so that door 318 covers outlets 31 6 A-C and thereby blocks the flow of bulk material out of outlets 31 6 A-C, as shown in FIGS. 22 , 24 , and 26 .
- Outlets 316 A-C can thus be selectively opened and closed by rotating door 318 back and forth through the use of actuator 322 .
- upper dome portion 310 can be formed with one, two, or four or more inlets 138 and corresponding outlets 316 .
- outlets 316 and openings 319 can be any number of different configurations as long as door 318 can selectively open and close outlets 316 .
- single door 318 can be replaced with a separate door for each outlet 316 .
- These doors can slide horizontally or pivot similar to door 154 ( FIG. 10 ) to selectively open and close the separate outlets 316 .
- a separate actuator can be used with each door.
- the cutter domes disclosed herein solve the problem of eliminating (or greatly reducing) the risk of material posting at the center of the storage vessel, while at the same time prevent the unwanted free-flow of bulk material out of the storage vessel, thereby ensuring first-in-first-out (FIFO) reclamation of stored bulk material.
- FIFO first-in-first-out
- the different disclosed embodiments of the cutter dome are merely examples of the inventive cutter dome and that other embodiments can also be used.
- different features of the different cutter domes can be mixed and matched to produce other embodiments.
- a variety of different reclaimers, hoppers, bases and drive assemblies can be used with the inventive cutter domes.
- the inventive cutter domes can be formed as part of a new reclaim system or can be retrofitted onto an existing reclaim system.
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- Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
- Filling Or Emptying Of Bunkers, Hoppers, And Tanks (AREA)
Abstract
Description
- Not applicable.
- 1. The Field of the Invention
- The present invention relates to cutter domes for use with a reclaim system within a storage vessel.
- 2. The Relevant Technology
- Silos are used for storing bulk material such as grains or powders. The bulk material is typically deposited into the silo through an opening formed at the top of the silo and is removed from the silo through an outlet centrally formed on the floor the silo. Bottom reclaim systems are often mounted on the floor of the silo for controlling movement of the bulk material to the outlet. The bottom reclaim system includes a base mounted adjacent to the outlet and an auger that outwardly projects from the base. The auger rotates about a central longitudinal axis thereof so as to inwardly draw the bulk material from the perimeter of the floor to the outlet. Furthermore, as the auger rotates about its longitudinal axis, the auger also revolves around the central outlet on the silo floor. As a result, the auger draws bulk material to the outlet from all areas on the silo floor.
- It is often desirable to have a first-in-first-out (FIFO) inventory control of the bulk material within the silo. This ensures that a portion of the bulk material does not stagnate within the silo. In cases where FIFO is important, it is desirable to have the outlet covered so that the bulk material directly above the outlet does not free flow into the outlet, thereby precluding FIFO inventory control. A solution to this problem has been to position a dome on the floor of the silo that covers the outlet and the base of the reclaim system. The dome has a cylindrical sidewall and a conical roof An opening is formed on the sidewall of the dome through which the auger passes. The auger draws the bulk material through the opening and to the outlet in a controlled manner. The dome prevents the free-flow of bulk material into the outlet, thereby helping to ensure the FIFO storage of the bulk material.
- The dome, however, introduces other problems. For example, even though the roof of the dome is conical, the bulk material can post on the roof of the dome. In posting, a significant portion of the entire amount of bulk material within the silo bears its load on a localized region. Specifically, the bulk material can vertically stack on the roof of the dome in a cohesive structure that remains stationary as opposed to flowing out toward the auger. In turn, this stacked bulk material above the roof can bridge outward until it eventually reaches the interior surface of the silo. In this scenario, large cavities can be produced within the silo as the reclaimer removes the freely movable bulk material from below the bridging bulk material.
- As a result of the posting of the bulk material on the dome, the dome and reclaimer can be subject to tremendous point-loading caused by the bulk material. That is, whereas the entire weight of the bulk material is typically uniformly carried over the entire floor of the silo, posting of the bulk material causes the weight of a large percentage of the bulk material to be concentrated on the dome. This point loading of the bulk material can result in failure of the dome and/or reclaimer. Furthermore, the stacking and bridging of the bulk material and the resulting formation of cavities precludes efficient operation of the reclaimer and prevents FIFO flow of bulk material within the silo. In some situations, movement of the bulk material within the silo can be completely stopped. In turn, disrupting the stacked bulk material within the silo to restore proper flow of the bulk material can be time consuming and dangerous.
- Various embodiments of the present invention will now be discussed with reference to the appended drawings. It is appreciated that these drawings depict only typical embodiments of the invention and are therefore not to be considered limiting of its scope.
-
FIG. 1 is a cut away perspective view of a storage vessel housing an inventive reclaim system; -
FIG. 2 is an enlarged perspective view of the reclaim system mounted on the floor of the storage vessel shown inFIG. 1 ; -
FIG. 3 is an enlarged perspective view of the reclaim system shown inFIG. 2 having a cutter dome; -
FIG. 4 is a cross sectional side perspective view of the reclaim system with cutter dome shown inFIG. 3 ; -
FIG. 5 is a perspective view of an upper portion of the cutter dome shown inFIG. 3 ; -
FIG. 6 is a bottom perspective view of the cutter dome portion shown inFIG. 5 ; -
FIG. 7 is a side perspective view of the cutter dome portion shown inFIG. 5 wherein a portion of the sidewall has been removed; -
FIG. 7A is a side view of the flutes of the cutter dome portion shown inFIG. 7 ; -
FIG. 8 is a top perspective view of the reclaim system shown inFIG. 3 with a door of the cutter dome in an open position; -
FIG. 9 is a top perspective view of the reclaim system shown inFIG. 8 wherein the door is in a closed position; -
FIG. 10 is a cross sectional side view of the cutter dome with a door for the upper dome portion in a partially open position; -
FIG. 11 is a side perspective view of an alternative embodiment of a cutter dome portion formed of flat flutes wherein a portion of the sidewall is removed; -
FIG. 12 is a side perspective view of another alternative embodiment of a cutter dome portion having radially outwardly projecting inlets; -
FIG. 13A is a side perspective view of an alternative embodiment of a cutter dome portion having a frusticonical roof portion that slopes radially inward; -
FIG. 13B is a side perspective view of alternative embodiment of a cutter dome portion having a frusticonical roof portion that slopes radially outward; -
FIG. 14 is a cross section side view of an alternative embodiment of a reclaim system having a cutter dome with an exposed central shaft and encircling flutes; -
FIG. 15 is a top plan view of the reclaim system shown inFIG. 14 ; -
FIG. 16 is a top plan view of the roof of the reclaim system shown inFIG. 14 without the shaft; -
FIG. 17 is an alternative embodiment of a reclaim system having a further alternative embodiment of a dome cutter; -
FIG. 18 is a top plan view of the reclaim system shown inFIG. 17 ; -
FIG. 19 is a top plan view of the roof of the cutter dome shown inFIG. 17 ; -
FIG. 20 is a cross sectional side perspective view of an alternative embodiment of a reclaim system having a cutter dome wherein an upper portion of the cutter dome is rotatable independent of a lower portion of the cutter dome; -
FIG. 21 is a top perspective view of an alternative embodiment of an upper dome portion with a door in an open position; -
FIG. 22 is a top perspective view of the upper dome portion shown inFIG. 21 with the door in a closed position; -
FIG. 23 is a bottom perspective view of the upper dome portion shown inFIG. 21 with the door in the open position; -
FIG. 24 is a bottom perspective view of the upper dome portion shown inFIG. 23 with the door in the closed position; -
FIG. 25 is a bottom plan view of the upper dome portion shown inFIG. 21 with the door in the open position; and -
FIG. 26 is a bottom plan view of the upper dome portion shown inFIG. 25 with the door in the closed position. - Depicted in
FIG. 1 is one embodiment of a reclaimsystem 10 incorporating features of the present invention and being used in association with astorage vessel 12.Storage vessel 12 is shown as comprising a substantiallycylindrical sidewall 14 that extends between afloor 16 and acap 18.Storage vessel 12 has aninterior surface 20 that bounds acompartment 22 that extends betweenfloor 16 andcap 18. Anaccess area 24 is formed belowfloor 16.Compartment 22 is configured to receive bulk material. As used in the specification and appended claims, the term “bulk material” is broadly intended to include powders, grains, sand, chips, granulated material, and other small diameter material that is capable of flowing under the force of gravity. Bulk materials typically have an average particle diameter size less than about 4 cm, commonly less than about 2 cm, and often less than 1 cm. Common examples of bulk materials include cement, talc, fly ash, salt, chemicals, fertilizers, wood chips, minerals, bauxite, coal, sulfur, beans, grains, such as wheat, barley, corn, oats, and rice, and flour and meal made from beans and grains. A variety of other small diameter materials can also function as bulk materials. -
Storage vessel 12 need not have a cylindrical configuration but can have a variety of different sizes, shapes and configurations. As such,storage vessel 12 can comprise a silo, tank, dome, or any other type of building structure that bounds a compartment in which bulk material can be stored. Bulk material is typically fed intocompartment 22 through an upper end ofstorage vessel 12 such as throughcap 18 or an upper end ofsidewall 14. This feeding can be accomplished through any conventional means such as conveyor belts, pumps, augers, or the like. As will be discussed below in greater detail, the bulk material is removed fromcompartment 22 through an opening infloor 16. Reclaimsystem 10 regulates the flow of the bulk material through the opening infloor 16. - As depicted in
FIG. 2 , reclaimsystem 10 generally comprises abase 26, ahopper 40, acutter dome 70, and areclaimer 180.Base 26 is mounted onfloor 16. As depicted inFIG. 3 ,base 26 has atop side 28 and an opposingbottom side 30. As shown inFIG. 4 ,base 26 has an interior surface 32 that bounds apassage 34 extending therethrough betweensides Passage 34 is the opening through which the bulk material passes out ofcompartment 22 ofstorage vessel 12. - In general,
base 26 comprises anouter structure 31 that encirclespassageway 34 and is rigidly secured tofloor 16 of storage vessel 12 (FIG. 1 ).Base 26 also includes aninner structure 33 that at least partially encirclespassageway 34 and is disposed radially inward and/or on top ofouter structure 31.Inner structure 33 is movably mounted onouter structure 31 so thatinner structure 33 can rotate aboutpassageway 34 relative toouter structure 31. A variety of different structures can be formed betweeninner structure 33 andouter structure 31 to facilitate smooth and easy movement ofinner structure 33. For example, a smooth wear plate, race, or other bearing assembly can be formed betweeninner structure 33 andouter structure 31. As discussed below in greater detail,cutter dome 70 is mounted oninner structure 33 ofbase 26 so thatcutter dome 70 can also rotate relative toouter structure 31 ofbase 26. - In the embodiment depicted,
outer structure 31 ofbase 26 is comprised of structural members, such as structural steel, and is mounted on or embedded withinfloor 16.Floor 16 is typically comprised of reinforced concrete. In alternative embodiments, however,outer structure 31 ofbase 26 can simply comprise the portion offloor 16 that surroundspassageway 34 extending throughfloor 16.Inner structure 33 can then be movably secured tofloor 16. - Mounted on
outer structure 31 ofbase 26 so as to project belowfloor 16 and into access area 24 (FIG. 1 ) ishopper 40.Hopper 40 has an encirclingsidewall 36 with anexterior surface 27 and aninterior surface 42 that each extend between anupper end 44 and an opposinglower end 46.Interior surface 42 bounds achamber 48 withinhopper 40. Anopening 50 is formed atupper end 44 ofhopper 40 so that open communication is provided betweenpassage 34 ofbase 26 andchamber 48 ofhopper 40. Likewise, anopening 52 is formed atlower end 46 ofhopper 40 in communication withchamber 48. As depicted inFIG. 2 ,doors 54 can be mounted atlower end 46 ofhopper 40 for selectively opening and closingopening 52. Although not depicted, a conveyor belt, transfer pipe, vehicle loading dock, railroad track or other means for transferring the bulk material away fromhopper 40 can be disposed belowdoors 54. As such, whendoors 54 are open, bulk material that is transferred intohopper 40 can be deposited on the means for transferring the bulk material so as to convey the bulk material away fromstorage vessel 12. - Returning to
FIG. 3 , rotatably mounted onbase 26 iscutter dome 70. Althoughcutter dome 70 is referred to as a “dome,” this is simply a term of art andcutter dome 70 need not have a conventional “dome” shaped configuration with an arched roof Rather,cutter dome 70 can have a substantially cylindrical configuration or a variety of other enclosing configurations. In the embodiment depicted, cutter dome comprises alower dome portion 72 and anupper dome portion 74. Arotational axis 76, about whichcutter dome 70 rotates, centrally extends down throughcutter dome 70. - As depicted in
FIG. 4 ,lower dome portion 72 includes alower sidewall 78 that extends from alower end 80 to anupper end 82. In the depicted embodiment,lower sidewall 78 has a tubular, cylindrical configuration that at least partially encirclesrotational axis 76.Lower sidewall 78 can also have a polygonal, irregular or other configuration.Lower end 80 is mounted oninner structure 33 ofbase 26 so thatcutter dome 70 rotates aboutrotational axis 76 concurrently withinner structure 33 ofbase 26.Lower sidewall 78 has aninterior surface 84 that bounds afirst chamber 86. An inlet opening 89 is formed atupper end 82 while an outlet opening 90 is formed atlower end 80. Outlet opening 90 communicates withpassage 34 ofbase 26 so that bulk material can pass therebetween. - A
collection opening 88 is formed throughlower sidewall 78 so that fluid communication is provided betweencompartment 22 of storage vessel 12 (FIG. 1 ) andfirst chamber 86.Collection opening 88 can be formed throughlower sidewall 78 so that a portion oflower sidewall 78 forms a continuous loop aboutrotational axis 76. Alternatively, collection opening 88 can be formed by forming a gap inlower sidewall 78 so thatlower sidewall 78 has a substantially C-shaped configuration. As will be discussed below in greater detail, a reclaimer, such as an auger extends through collection opening 88 for drawing bulk material intofirst chamber 86. - Turning to
FIG. 5 ,upper dome portion 74 comprises anupper sidewall 94 that is mounted on upper end 82 (FIG. 4 ) oflower sidewall 78 and that extends between alower end 96 and anupper end 98.Upper sidewall 94 has a substantially cylindrical configuration that completely encirclesrotational axis 76.Upper sidewall 94 can also have a polygonal, irregular, or other configuration. As depicted inFIG. 6 ,upper sidewall 94 has aninterior surface 100 that bounds asecond chamber 102. Returning toFIG. 5 ,upper end 98 ofupper sidewall 94 terminates at aperimeter edge 104.Perimeter edge 104 is comprised of threeequal arced segments 106A-C each having a substantially identical configuration.Arced segment 106A comprises atop edge 108A that extends from afirst end 110A to an opposingsecond end 112A.Top edge 108A has a constant radius relative torotational axis 76 and downwardly slopes fromfirst end 110A tosecond end 112A. As a result,first end 110A is positioned higher alongrotational axis 76 thansecond end 112A. -
Arced segment 106A also comprises ashoulder 114A that downwardly projects from first end 11A. In one embodiment,shoulder 114A extends in a plane that is parallel to and aligned withrotational axis 76. In alternative embodiments,shoulder 114A can extend in a plane that intersects withrotational axis 76 at an angle.Arced segment 106A can be configured so that an angle θ1 is formed betweentop edge 108A andshoulder 114A in a range between about 45° to about 225° with about 65° to about 115° or about 80° to about 110° being more common. Other angles can also be used. It is also appreciated thatshoulder 114A need not be straight but can also be curved.Arced segments 106B and 106C have the same configuration as arcedsegment 106A and are identified by like reference characters. It is noted that the second end 112 of each arced segment 106 intersects with shoulder 114 of the adjacent arced segment 106. - Centrally disposed within
second chamber 102 ofupper dome portion 74 is ashaft 120 that extends alongrotational axis 76.Upper dome portion 74 also comprises aroof 122 that extends betweenperimeter edge 104 andshaft 120. In the depicted embodiment,roof 122 is comprised of threeequal roof segments 124A-C each having substantially the same circular segment configuration.Roof segment 124A comprises aninside edge 126A that is secured toshaft 120, a curvedoutside edge 128A that extends alongtop edge 108A ofperimeter edge 104, acutting edge 130A that extends fromshaft 120 tofirst end 110A oftop edge 108A, and aback edge 132A that extends fromshaft 120 tosecond end 112A oftop edge 108A. Becausetop edge 108A downwardly slopes as previously discussed,outside edge 128A ofroof segment 124A has a complimentary slope. Furthermore,roof segment 128A is curved so thatinside edge 126A ofroof segment 124A curves alongshaft 120 at substantially the same angle asoutside edge 128A. This curve is such that ifroof segment 124A was extended,segment 124A would encircleshaft 120 in a downwardly extending helical configuration. -
Roof segments shaft 120 andtop edges 108B and 108C, respectively. As a result of the height ofshoulders 114A-C,elongated inlets 138A-C are formed between cutting edge 130 of each roof segment 124 and back edge 132 of the adjacent roof segment 124. For example,inlet 138C extends between shoulder 114C andshaft 120 betweencutting edge 130C and backedge 132A. The height ofinlet 138C depends on the height ofshoulders 114A-C and the angle at which theroof segments 124A-C are disposed.Inlets 138A-C provide fluid communication betweencompartment 22 of storage vessel 12 (FIG. 1 ) andsecond chamber 102 ofupper dome portion 74. - As depicted in
FIG. 7 , disposed withinsecond chamber 102 are three slopedflutes 140A-C. Eachflute 140A-C is disposed betweenshaft 120 andupper sidewall 94 and extends from the back edge 132 of a corresponding roof segment 124 to a termination point located above adrop box 142 that is formed withinsecond chamber 102. Eachflute 140A-C downwardly slopes in a helical path aboutshaft 120. Furthermore, eachflute 140A-C partially bounds acorresponding passageway 143A-C through which the bulk material travels as it passes from acorresponding inlet 138A-C to dropbox 142. Eachpassageway 143A-C also downwardly slopes in a helical path aboutshaft 120. - Each
flute 140A-C slopes down towarddrop box 142 so that the bulk material travels downward ascutter dome 70 is rotated. However, flutes 140A-C are typically disposed at an angle less than the angle of repose of the bulk material withincompartment 22 ofstorage vessel 12. This helps prevent the bulk material from freely flowing downpassageways 143A-C. As depicted inFIG. 7A , eachflute 140A-C typically slopes at an angle θ2, which is relative to a plane that is normal torotational axis 76, that is in a range between about 5° to about 30° and more commonly in a range between about 10° to about 20°. Other ranges can also be used. The bulk material typically has an angle of repose withincompartment 22 that is greater than about 30° relative to the horizontal. - Returning to
FIG. 7 ,drop box 142 comprises afirst partition wall 144 that extends along the height ofupper sidewall 94, an opposingsecond partition wall 145 that downwardly projects from the terminal end offlute 140C, anoutside partition wall 146 that slopes inwardly and extends between the outside ends ofpartition walls inside partition wall 147 that extends between the inside ends ofpartition walls outlet 152 that provides fluid communication betweenfirst chamber 86 of lower dome portion 72 (FIG. 4 ) andsecond chamber 102 ofupper dome portion 74. A door 154 (FIG. 10 ) is hingedly mounted oninside partition wall 147 and can be used for selectively opening andclosing outlet 152. - As will be discussed below in greater detail, during
operation cutter dome 70 is rotated onbase 26 aboutrotational axis 76. Ascutter dome 70 is rotated, the bulk material sitting onroof 122 passes intoinlets 138A-C, travels downpassageways 143A-C, and passes throughoutlet 152 indrop box 142 intofirst chamber 86 oflower dome portion 72. The bulk material then travels down throughpassage 34 inbase 26 and intochamber 48 ofhopper 40. The fact thatinlets 138A-C are positioned below cuttingedges 130A-C enables cuttingedges 130A-C to efficiently cut away at the bulk material ascutter dome 70 is rotated, thereby ensuring that the bulk material is fed intopassageways 143A-C. - Is appreciated that
cutter dome 70 can come in a variety of different configurations. By way of example and not by limitation, in the depicted embodimentupper dome portion 74 is separately formed and secured tolower dome portion 72 such as by bolting, welding, or the like. In an alternative embodiment, it is appreciated that thelower sidewall 78 andupper sidewall 94 can be formed from one or more continuous members that extend the full height oflower sidewall 78 andupper sidewall 94. Likewise, the depicted embodiment includes threeinlets 138A-C and threeseparate flutes 140A-C. In alternative embodiments,cutter dome 70 can be formed from a single inlet 138 and a single flute 140 or, alternatively, from two or four or more inlets 138 and flutes 140. - In still other embodiments, shoulders 114A-C can be eliminated so that
roof 122 is substantially flat.Inlets 138A-C can be formed onflat roof 122 leading topassageways 143A-C. In contrast toroof 122 being flat,roof 122 can be conical, domed shaped, semi-spherical or any other configuration. In each of these different configurations, shoulders 114A-C can be formed so as to expose cuttingedges 130A-C or shoulders 114A-C can be eliminated so thatinlets 138A-C are formed flat on the roof surface. - Furthermore, in the depicted embodiment flutes 140A-C are secured to
roof segments 124A-C such as by welding, bolting or other conventional methods. In alternative embodiments, eachroof segment 124A-C can be integrally formed as a unitary member with acorresponding flute 140A-C. Furthermore, eachflute 140A-C is shown as only partially encirclingshaft 120. In alternative embodiments, eachflute 140A-C can form one or more complete helical revolutions aboutshaft 120. Further alternative embodiments will be discussed below in greater detail. - Returning to
FIG. 3 , in the depictedembodiment reclaimer 180 comprises anelongated auger 182 having afirst end 184 that is disposed within thefirst chamber 86 and an opposingsecond end 186 that is disposed outside ofcutter dome 70 but withinstorage vessel 12.Auger 182 comprises acentral shaft 188 having a centrallongitudinal axis 190 extending along the length thereof and one ormore threads 192 helically encircling and extending along the length ofshaft 188.Auger 182 passes out offirst chamber 86 by passing throughcollection opening 88. - As depicted in
FIG. 4 , disposed withinchamber 48 ofhopper 40 andfirst chamber 86 oflower dome portion 72 is adrive train 204. Drivetrain 204 has afirst end 205 that is coupled by a belt to a drive motor 206 (FIG. 3 ). Drivetrain 204 has an opposingsecond end 208 that is coupled withfirst end 184 ofauger 182. As such, drivemotor 206 and drivetrain 204 facilitate rotation ofauger 182 about axis 190 (FIG. 3 ) which in turn causes auger 182 to draw the bulk material intocollection opening 88. As depicted inFIG. 20 ,second end 208 ofdrive train 204 andfirst end 184 of auger 182 (FIG. 3 ) are supported bysupport members 210 that extend frominner structure 33 ofbase 26 to drivetrain 204. As such,second end 208 ofdrive train 204 andfirst end 184 ofauger 182 rotate concurrently withinner structure 33 ofbase 26 andcutter dome 70 aboutrotational axis 76. - As shown in
FIG. 3 , disposed parallel to and extending along the length ofauger 182 is asupport arm 194.Support arm 194 has afirst end 195 disposed withinfirst chamber 86 and an opposingsecond end 197 disposed adjacent tosecond end 186 ofauger 182.Second end 186 ofauger 182 is rotatable mounted tosecond end 197 ofsupport arm 194 to provide structural stability to auger 188. Furthermore,support arm 194 has aninside face 196 having a concave configuration and that extends alongauger 182. Insideface 196 helps to capture bulk material betweenthreads 192 and insideface 196 so that the bulk material is efficiently drawn down along the length ofauger 182 and intocollection opening 88. - As better depicted in
FIG. 8 , adrive shaft 198 is disposed within and extends along the length ofsupport arm 194. Driveshaft 198 is rotated by amotor 199. Returning toFIG. 3 ,drive shaft 198 has adistal end 201 located atsecond end 197 ofsupport arm 194.Distal end 201 couples with a track, such as through the use of a gear. The track is formed on the interior surface of 20 ofstorage vessel 12 adjacent tofloor 16 so as to encirclefloor 16. Alternatively, the track can be formed onfloor 16 at the perimeter edge thereof so as to encirclefloor 16. Driveshaft 198 is engaged with the track so that rotation ofdrive shaft 198 causesdistal end 210 ofdrive shaft 198 to slowly move along the length of the track. In turn, this movement ofdrive shaft 198 causessecond end 197 ofsupport arm 194 andsecond end 186 ofauger 182 to also move along the track. In turn, movement of the second end ofsupport arm 194 andauger 182 along the track facilitates the rotation ofsecond end 208 ofdrive train 204,first end 184 ofauger 182,inner structure 33 ofbase 26, andcutter dome 70 to concurrently rotate aboutrotational axis 76. -
Reclaimer 180,hopper 40,base 26 and the drive systems disclosed herein can be purchased from Laidig Systems, Inc. located in Mishawaka, Indiana. In alternative embodiments, it is appreciated that other conventional reclaimers, hoppers, bases and drive systems can be used with the inventive cutter domes of the present invention. For example, in contrast to reclaimer 180 comprising an auger,reclaimer 180 can comprise different rotating screw configurations, belt conveyors with or without paddles, chain conveyors, and other types of continuous dragging or transport systems that are commonly used for movement of bulk material and which could function for moving bulk material intofirst chamber 86. - Turning to
FIGS. 8 and 9 , adoor 214 encirclesshaft 188 ofauger 182 and can selectively move alongshaft 188.Door 214 is moveable between an open position and a closed position. In the open position shown inFIG. 8 ,door 214 is drawn back from collection opening 88 intofirst chamber 86 so that bulk material can be drawn intocutter dome 70 through collection opening 88 during rotation ofauger 182. In the closed position shown inFIG. 9 ,door 214 is moved forward so as to close offcollection opening 88. The closing of collection opening 88 through the use ofdoor 214 enablescutter dome 70 andhopper 40 to be emptied of bulk material so thatcutter dome 70 andhopper 40 can be accessed throughhopper 40 for maintenance and/or repair of components therein.Door 214 is selectively moved between the open and close position as a result of alinkage 216 operated by ahydraulic piston 218.Linkage 216 used to closedoor 214 cams over, thereby lockingdoor 214 into position in case of hydraulic pressure loss. Other mechanisms can also be used for selectively opening and closingdoor 214. - Turning to
FIG. 10 , the opening and closing ofdoor 214 also facilitates selective opening and closing ofdoor 154 that selectively coversoutlet 152 ofupper dome portion 74. Specifically, as previously discussed,door 154 is hingedly mounted toinside partition wall 147. Whendoor 214 is moved to the open position, the force of gravity enablesdoor 154 to rotate downward into an open position so that bulk material can pass throughoutlet 152. Asdoor 154 is moved to the closed position, atop end 222 ofdoor 214 pushes againstdoor 154 causing it to rotate upward into a closed position and thereby close offoutlet 152. Whendoor 214 is in the close position,top end 222 ofdoor 214 pushes againstdoor 154 so as to prevent unwanted opening ofdoor 154. If desired, taperedrams 223 or other structures can be formed attop end 222 ofdoor 214 to help facilitate closing ofdoor 154. Again, the closing ofdoor 154 is desirable so that all the bulk material can be removed from withincutter dome 70 andhopper 40 for accessing the mechanisms therein. - It is appreciated that in
alternative embodiments door 154 can be opened using a variety of different mechanisms such as screw drives, hydraulic pistons or a variety of other conventional systems. As such,doors door 154, ensures concurrent closure of both doors, and provides an easy retrofit of adding anupper dome portion 74 on an existinglower dome portion 72. - During operation,
doors Auger 182 begins to rotate aboutrotational axis 190 so as to draw the bulk material throughcollection opening 88 and intofirst chamber 86 ofcutter dome 70. Simultaneously,cutter dome 70 andauger 182 begin to slowly rotate aboutrotational axis 76 as a result of the rotation ofdrive shaft 198.Cutter dome 70 andauger 182 typically rotate at a rate of about 1-3 degrees per minute although other rates can also be used. The movement ofauger 182 overfloor 16 ensures a uniform draw down of the bulk material overfloor 16 ofstorage vessel 12. Ascutter dome 70 is rotated, the bulk material positioned abovecutter dome 70 is drawn intoinlets 138A-C where it passes down throughsecond chamber 102 and intofirst chamber 86 throughoutlet 152. - The removal of the bulk material from above
cutter dome 70 helps to maintain movement of the bulk material directly abovecutter dome 70. As a result, the bulk material is precluded from setting up or becoming stationary, thereby precluding “posting” or “bridging” of the bulk material abovecutter dome 70. Furthermore, the slow rotation ofcutter dome 70 controls the material flow such that “rat holing” does not develop. Angling the flutes at a angle lower than the angle of repose of the bulk material also preclude unwanted free flow of material. The majority of the bulk material is collected throughcollection opening 88. As a result, the bulk material is primarily processed throughstorage vessel 12 in a first-in-first-out inventory. - Once the bulk material passes into
first chamber 86 from eithercollection opening 88 or throughcutter dome 70, the bulk material flows under the force of gravity throughpassageway 34 inbase 26 and intochamber 48 ofhopper 40. The bulk material is then transferred out ofhopper 40 throughdoors 54 using any conventional means such as trucks, conveyor belts, pumps, or the like. - Depicted in
FIG. 11 is an alternative embodiment of anupper dome portion 74A ofcutter dome 70. Like elements betweenupper dome portion upper dome portion 74,roof segments 124A-C and flutes 140A-C are bent or contoured so as to extend in a smooth helical path. Inupper dome portion 74A, eachroof segment 124A-C is comprised of a flat plate in the form of a circular segment that extends fromshaft 120 toperimeter edge 104. As a result, eachinlet 138A-C has a substantially triangular configuration. - With regard to
flutes 140A-C that extend in a helical path alongshaft 120, to maintain the helical orientation while maintaining the use of only flat plates, theflutes 140A-C are comprised of a series of flatcircular segment plates 230 having a configuration similar to theflat roof segments 124A-C. Eachsegment plate 230 has aninside edge 234 that is connected toshaft 120, an opposing arcedoutside edge 236 that connects to sidewall 94, and afirst edge 238 and an opposingsecond edge 240 extending therebetween.Plates 230 are secured in sequential order withoutside edges 236 being aligned longitudinally and adjacentinside edges 234 being vertically staggered alongshaft 120. Atriangular riser 232 extends betweensecond edge 240 of oneplate 230 andfirst edge 238 of theadjacent plate 230, thereby forming a stepped helical path aboutshaft 120. - In the
upper dome portion 74 depicted inFIG. 5 ,inlets 138A-C extended only alongroof 122. In alternative embodiments,upper dome portion 74 can also be formed so that the inlets for receiving the bulk material project out beyondupper sidewall 94. By way of example and not by limitation, depicted inFIG. 12 is an alternative embodiment of anupper dome portion 74B ofcutter dome 70 where like elements are identified by like reference characters. In this embodiment,upper sidewall 94 is formed from threesidewall sections 246A-C. Each sidewall section 246 extends from aleading edge 248 to atail edge 250. Eachsidewall section 246A-C radially inwardly curves towardshaft 120 as it extends between ends 248 and 250. As a result, leadingend 248 has a radius fromshaft 120 that is greater than the radius betweenshaft 120 andtail edge 250. As a result of this configuration,inlets 138A-C now outwardly project beyond the adjacent sidewall section 246. Furthermore,elongated inlets 252A-C extends along the length of each sidewall section 246. This inlet again captures bulk material and transfers it intofirst chamber 86 ascutter dome 70 is rotated. - In the previous depicted embodiments,
inlets 138A-C extended all the way toupper sidewall 94. In alternative embodiments, however, theinlets 138A-C need not extend all the way to sidewall 94. For example, depicted inFIG. 13A is a further embodiment of an upper dome portion 74C ofcutter dome 70 where like elements are identified by like reference characters. Upper dome portion 74C includesupper sidewall 94. Howeverroof 122 comprises an outer roof portion 254 and aninner roof portion 256. Outer roof portion 254 has a frusticonical configuration that slopes down and radially inward towardinner roof portion 256. In turn,inner roof portion 256 comprisesroof segments 124A-C as previously discussed with regard toupper dome portion 74. In this regard, outer roof 254 functions to funnel bulk materials down toinner roof portion 256 which in turn transfers the bulk material tofirst chamber 86. - Depicted in
FIG. 13B is a further alternative embodiment of an upper dome portion 74D. Upper dome portion 74D is substantially the same as upper dome portion 74C except that outer roof portion 254 has been replaced with an outer roof portion 258. Outer roof portion 258 also has a frusticonical configuration but slopes down and away frominner roof portion 256. As a result, outer roof portion 258 facilitates moving the bulk material off ofcutter dome 70. In both of the above embodiments, it is appreciated that the inner and outer roof portions can rotate concurrently with each other and withlower dome portion 72. Alternatively,inner roof portion 256 can rotate independent of the outer roof portion and/orlower dome portion 72. For example, a drive motor can be used to rotateinner roof portion 256 at a speed greater thanlower dome portion 72. - Depicted in
FIGS. 14 and 15 is an alternative embodiment of acutter dome 70A wherein like elements are identified by like reference characters.Cutter dome 70A compriseslower dome portion 72 and anupper dome portion 74E.Upper dome portion 74E comprises aroof 260 mounted onlower dome portion 72.Roof 260 comprises acircular frusticonical sidewall 262 that slopes radially inwardly and up to acentral recess 264.Recess 264 is bounded by acircular sidewall 265 and afloor 266. As depicted inFIG. 16 ,floor 266 has a pair ofopenings 268A and B which are selectively opened and closed by doors 270A and B. Although not shown, it is appreciated thatopenings 268A and B connect by passageways to drop box 142 (FIG. 7 ). - Returning to
FIG. 14 , extending through floor 270 isshaft 120. One ormore flutes 272 are helically formed on the exterior ofshaft 120.Flutes 272 projects out so as to be adjacent to sidewall 265 ofrecess 264. As a result,flutes 272 block the free flow of bulk material intoopenings 268A and B. Again, during operation,lower dome portion 72 andupper dome portion 74 can rotate concurrently so that asshaft 120 is rotated, the bulk material passes down alongflutes 272 and intoopenings 268A and B. Alternatively, a separate drive motor withinlower dome portion 72 can be used to selectively rotateshaft 120 independent oflower dome portion 72 androof 260. In an alternative embodiment forcutter dome 70A, it is also appreciated thatroof 260 can be configured similar to outer roof portion 254 (FIG. 13A ) so that the bulk material is funneled towardrecess 264 as opposed to away fromrecess 264. - Turning to
FIGS. 17-19 is a further alternative embodiment of acutter dome 70B incorporating features of the present embodiment. Again, like elements are identified by like reference characters.Cutter dome 70B compriseslower dome portions 72 having aroof 280 formed thereon.Roof 280 has a pair ofopenings 282A and B that are selectively opened and closed bydoors 284A and B respectively.Shaft 120 centrally extends throughroof 280. Aflute 286 is mounted on and helically encircles the exterior surface ofshaft 120. A drive mechanism disposed withinlower dome portion 72 facilitates rotation ofshaft 120 independent oflower dome portion 72. Withdoors 284A and B open, rotation ofshaft 120 causes the bulk material to travel down the flute and intoinlets 282A and B. The bulk material then passes frominlets 282A and B throughlower dome portion 72 and intohopper 40.Flute 286 is intended to project out to the edge ofroof 280 so as to preclude any posting of the bulk material onroof 280. - In any of the foregoing examples, is appreciated that
upper dome portion 74 can rotate independent oflower dome portion 72. That is,upper dome portion 74 can rotate at a different speed thanlower dome portion 72. Depicted inFIG. 20 is one embodiment of how to facilitate such movement betweendome portions upper dome portion 74 connects withinlower dome portion 72 on atrack 290. Track 290 permits rotation ofupper dome portion 74 relative to lowerdome portion 72 and can comprise a smooth wear plate, race, bearing assembly or the like. Anannular engagement track 292 is disposed on the interior surface ofupper dome portion 74 having a plurality ofteeth 294 formed thereon. Agear 296 engagesteeth 294. Adrive assembly 298 rotatesgear 296 which in turn facilitates rotation ofupper dome portion 74 relative to lowerdome portion 72. In turn, however,lower dome portion 72 and drive assembly 298 rotate relative toouter structure 31 ofbase 26. Depicted inFIGS. 21-26 is a further alternative embodiment of anupper dome portion 310 incorporating features of the present invention.Upper dome portion 310 is similar toupper dome portion 74 shown inFIGS. 5-7 and like elements are identified by like reference numbers. It is noted that part of theupper sidewall 94 ofupper dome portion 310 is removed to help show the internal structure. - Similar to
upper dome portion 74,upper dome portion 310 is shown having threeroof segments 124A-C and threeinlets 138A-C. However, in contrast toupper dome portion 74 wherein all three of passageways 143 terminate at acommon outlet 152,upper dome portion 310, as shown inFIG. 21 , includes threeflutes 312A-C leading from correspondinginlets 138A-C, respectively. Each flute 312 A-C extends a short distance in a downward, helical path aboutshaft 120 and terminates, as shown inFIG. 23 , at aseparate outlet 316A-C, respectively. That is, eachflute 312A-C which partially bounds acorresponding passageway 314A-C terminates at a separate,isolated outlet 316A-C. Eachoutlet 316A-C is shown having a wedge shaped configuration and downwardly communicates withfirst chamber 86 of lower dome portion 72 (FIG. 4 ). Becausepassageways 314A-C are shorter than the passageways ofupper dome portion 74 and each exits through itsown outlet 316A-C, there is less chance of bulk material clogging withinupper dome portion 310. - As with
upper dome portion 74, however, it is desirable to be able to selectivelyclose outlets 316A-C so thatlower dome portion 72 can be accessed without risk of being trapped by the bulk material. To that end, adoor 318 is mounted withinsecond chamber 102 belowoutlets 316A-C. Door 318 is shown in the form of a circular plate having three openings 319A-C. Each opening 319A-C has a wedge shaped configuration complementary tooutlets 316A-C. Door 318 centrally rotates aboutshaft 120 and is movably supported around it perimeter edge bysupports 320 secured toupper sidewall 94. Abeam 336 is shown spanning between opposing sides ofupper sidewall 94 and supportsshaft 120. - As shown in
FIGS. 25 and 26 ,door 318 is moved by anactuator 322.Actuator 322 includes abody 324 having afirst end 328 hingedly mounted toupper sidewall 94 and an opposingsecond end 330. Apiston 326 has afirst end 332 slidably mounted withinsecond end 330 ofbody 324 and an opposing second 334 hingedly mounted to a bottom surface ofdoor 318. In one embodiment,actuator 322 can comprise a pneumatic or hydraulic piston. In other embodiment,actuator 322 can comprise a screw drive or any other actuator that can expand and contract. -
Actuator 322 anddoor 318 are movable between an open and closed position. In the open position as shown inFIGS. 21 , 23, and 25, openings 319A-C on door 318 (FIG. 23 ) are aligned withoutlets 316A-C, respectively, so that the bulk material can freely flow out throughoutlets 316A-C and intofirst chamber 86. Upon actuation ofactuator 322,piston 326 advances out ofbody 324, thereby causingdoor 318 to rotate so thatdoor 318 coversoutlets 31 6A-C and thereby blocks the flow of bulk material out ofoutlets 31 6A-C, as shown inFIGS. 22 , 24, and 26.Outlets 316A-C can thus be selectively opened and closed by rotatingdoor 318 back and forth through the use ofactuator 322. - As discussed above with regard to
upper dome portion 74, it is appreciated thatupper dome portion 310 can be formed with one, two, or four or more inlets 138 and corresponding outlets 316. Likewise, outlets 316 and openings 319 can be any number of different configurations as long asdoor 318 can selectively open and close outlets 316. Furthermore,single door 318 can be replaced with a separate door for each outlet 316. These doors can slide horizontally or pivot similar to door 154 (FIG. 10 ) to selectively open and close the separate outlets 316. A separate actuator can be used with each door. - The cutter domes disclosed herein solve the problem of eliminating (or greatly reducing) the risk of material posting at the center of the storage vessel, while at the same time prevent the unwanted free-flow of bulk material out of the storage vessel, thereby ensuring first-in-first-out (FIFO) reclamation of stored bulk material. It is appreciated that the different disclosed embodiments of the cutter dome are merely examples of the inventive cutter dome and that other embodiments can also be used. For example, different features of the different cutter domes can be mixed and matched to produce other embodiments. Furthermore, a variety of different reclaimers, hoppers, bases and drive assemblies can be used with the inventive cutter domes. It is also noted that the inventive cutter domes can be formed as part of a new reclaim system or can be retrofitted onto an existing reclaim system.
- Accordingly, the present invention may be embodied in other specific forms without departing from its spirit or essential characteristics. The described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the invention is, therefore, indicated by the appended claims rather than by the foregoing description. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope.
Claims (28)
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US8177470B2 US8177470B2 (en) | 2012-05-15 |
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US9206000B1 (en) * | 2010-02-19 | 2015-12-08 | Sudenga Industries, Inc. | Bin sweep collector ring assembly |
US11066256B2 (en) * | 2019-03-14 | 2021-07-20 | Ctb, Inc. | Grain bin powersweep with sump shaft aperture sealing cover plate assembly |
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US9156608B1 (en) * | 2012-07-13 | 2015-10-13 | R.A. Skaife Enterprises, Inc. | Protector for a discharge sump of a storage bin |
US10227188B1 (en) * | 2017-02-17 | 2019-03-12 | Duane Cyril Chaon | Bin sweep pivots |
US10160605B1 (en) | 2018-02-23 | 2018-12-25 | Laidig Systems, Inc. | Oscillating auger support |
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US20060104757A1 (en) * | 2004-09-28 | 2006-05-18 | Klaus-Sweerich Schroder | Device for conveying bulk material |
US20080131242A1 (en) * | 2006-10-09 | 2008-06-05 | Thomas John Duffy | Grain bin discharge guard and power sweep |
Cited By (3)
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US9206000B1 (en) * | 2010-02-19 | 2015-12-08 | Sudenga Industries, Inc. | Bin sweep collector ring assembly |
US9206001B1 (en) * | 2010-02-19 | 2015-12-08 | Sudenga Industries, Inc. | Bin sweep collector ring assembly |
US11066256B2 (en) * | 2019-03-14 | 2021-07-20 | Ctb, Inc. | Grain bin powersweep with sump shaft aperture sealing cover plate assembly |
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US8177470B2 (en) | 2012-05-15 |
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